Coordinate representation of the momentum operator

MSLion
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The position operator in coordinate representation is:
Xab=aδ(a-b)
this is diagonal as expected

The momentum operator turns out to look like
Pab=-ih∂aδ(a-b)

Now, this is not supposed to be diagonal because it does not commute with X.
However it looks pretty diagonal to me.

What am I missing?
 
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The momentum operator is not what you wrote here. It is equal to:
P_{ab} = e^{i(a-b)}
with some scaling factors.
 
haael said:
The momentum operator is not what you wrote here. It is equal to:
P_{ab} = e^{i(a-b)}
with some scaling factors.

What exactly are you saying?

Anyone familiar with quantum mechanics in dirac notation?
 
MSLion said:
The position operator in coordinate representation is:
Xab=aδ(a-b)
this is diagonal as expected

The momentum operator turns out to look like
Pab=-ih∂aδ(a-b)

Now, this is not supposed to be diagonal because it does not commute with X.
However it looks pretty diagonal to me.

What am I missing?

I don't see how it looks diagonal. For something to be diagonal, it needs to be multiplied by a delta function. An example of a diagonal matrix is:

Oab=δ(a-b) f(a,b)

for arbitrary function f(a,b).

The delta function is essentially the identity matrix, and f(a,b) are the diagonal components.
 
From what I understood on distributions the support of the derivative of a distribution is contained within the support of the original distribution.

Therefore ∂aδ(a-b) should be zero wherever δ(a-b) is.
 
MSLion said:
From what I understood on distributions the support of the derivative of a distribution is contained within the support of the original distribution.

Therefore ∂aδ(a-b) should be zero wherever δ(a-b) is.

Distributions are supported on functions ##f(a)##, not on the domain of the functions themselves. Given a function ##f(a)##, we have ##\delta[f]=f(0)## and ## \delta'[f]=f'(0)##. These are generally not equal. The same argument can be made for delta functions which are shifted away from the origin.

##\delta'## is as independent of ##\delta## as an ordinary function is from its derivative. There's no unitary operator that can map one to another (for all test functions ##f##).
 

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